Moment of a force about a point

AI Thread Summary
A 2.9 lb force is applied to a lever, creating a counterclockwise moment of 17 lb-in about point A. The equation for the moment is established as M_a = (F_x)(d_y) + (F_y)(d_x), leading to the equation 17 = (2.9sin(alpha))(4.8) + (2.9cos(alpha))(3.4). To solve for alpha, a trigonometric identity can be used to express sin(alpha) in terms of cos(alpha), facilitating the calculation of cos(alpha). The final solutions for alpha are determined to be 49.9 degrees or 59.4 degrees. This approach effectively utilizes trigonometric relationships to solve for the angle in the context of moments.
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Homework Statement


This one's easy. A 2.9 lb force (P) is applied to a lever. Determine the value of alpha knowing that the moment of P about A is counterclockwise (+) and has a magnitude of 17 lb-in.


Homework Equations



Moment about a = (Force of x-component)(distance from a to Force point) + (F_y-comp)(dist. to foce)

M_a = (F_x)(d_y) + (F_y)(d_x)

Answer: alpha = 49.9 degrees or 59.4 degrees

The Attempt at a Solution



17 = (2.9sin(alpha))(4.8) + (2.9cos(alpha))(3.4)

how do I solve for alpha?
 

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Use a trig identity to express sinα in terms of cosα (or vice versa). Then you can solve for cosα.
 
can I use sin A = cos(pi/2 - A)?
 
Use sin2α + cos2α = 1. (Rearrange it.)
 

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